// Copyright (C) 2005, 2006 International Business Machines and others.
// All Rights Reserved.
// This code is published under the Eclipse Public License.
//
// Authors:  Andreas Waechter              IBM    2005-10-127

#include "LuksanVlcek4.hpp"

#include <cmath>
#include <cstdio>

using namespace Ipopt;

LuksanVlcek4::LuksanVlcek4(
   Number g_l,
   Number g_u
)
{
   g_l_ = g_l;
   g_u_ = g_u;
}

bool LuksanVlcek4::InitializeProblem(
   Index N
)
{
   N_ = N;
   if( N_ <= 1 || 4 * ((N_ + 2) / 4) != N_ + 2 )
   {
      printf("N needs to be at least 2 and N+2 needs to be a multiple of 4.\n");
      return false;
   }
   return true;
}

// returns the size of the problem
bool LuksanVlcek4::get_nlp_info(
   Index&          n,
   Index&          m,
   Index&          nnz_jac_g,
   Index&          nnz_h_lag,
   IndexStyleEnum& index_style
)
{
   // The problem described in LuksanVlcek4.hpp has 4 variables, x[0] through x[3]
   n = N_ + 2;

   m = N_ - 2;

   nnz_jac_g = 3 * m;

   nnz_h_lag = n + n - 1;

   // use the C style numbering of matrix indices (starting at 0)
   index_style = TNLP::C_STYLE;

   return true;
}

// returns the variable bounds
bool LuksanVlcek4::get_bounds_info(
   Index   n,
   Number* x_l,
   Number* x_u,
   Index   m,
   Number* g_l,
   Number* g_u
)
{
   // none of the variables have bounds
   for( Index i = 0; i < n; i++ )
   {
      x_l[i] = -1e20;
      x_u[i] = 1e20;
   }

   // Set the bounds for the constraints
   for( Index i = 0; i < m; i++ )
   {
      g_l[i] = g_l_;
      g_u[i] = g_u_;
   }

   return true;
}

// returns the initial point for the problem
bool LuksanVlcek4::get_starting_point(
   Index   n,
   bool    init_x,
   Number* x,
   bool    init_z,
   Number* /*z_L*/,
   Number* /*z_U*/,
   Index   /*m*/,
   bool    init_lambda,
   Number* /*lambda*/
)
{
   if( !init_x || init_z || init_lambda )
   {
      return false;
   }

   // set the starting point
   for( Index i = 0; i < n / 4; i++ )
   {
      x[4 * i] = 1.;
      x[4 * i + 1] = 2.;
      x[4 * i + 2] = 2.;
      x[4 * i + 3] = 2.;
   }

   return true;
}

// returns the value of the objective function
bool LuksanVlcek4::eval_f(
   Index         /*n*/,
   const Number* x,
   bool          /*new_x*/,
   Number&       obj_value
)
{
   obj_value = 0.;
   for( Index i = 0; i < N_ / 2; i++ )
   {
      Number e0 = exp(x[2 * i]);
      Number e0mx1 = e0 - x[2 * i + 1];
      Number x1mx2 = x[2 * i + 1] - x[2 * i + 2];
      Number x2mx3 = x[2 * i + 2] - x[2 * i + 3];
      Number t = tan(x2mx3);
      Number x3m1 = x[2 * i + 3] - 1.;
      obj_value += pow(e0mx1, 4) + 100. * pow(x1mx2, 6) + pow(t, 4) + pow(x[2 * i], 8) + x3m1 * x3m1;
   }

   return true;
}

// return the gradient of the objective function grad_{x} f(x)
bool LuksanVlcek4::eval_grad_f(
   Index         /*n*/,
   const Number* x,
   bool          /*new_x*/,
   Number*       grad_f
)
{
   grad_f[0] = 0.;
   grad_f[1] = 0.;
   for( Index i = 0; i < N_ / 2; i++ )
   {
      Number e0 = exp(x[2 * i]);
      Number e0mx1 = e0 - x[2 * i + 1];
      Number x1mx2 = x[2 * i + 1] - x[2 * i + 2];
      Number x2mx3 = x[2 * i + 2] - x[2 * i + 3];
      Number x3m1 = x[2 * i + 3] - 1.;
      Number dt = 4. * pow(tan(x2mx3), 3) / pow(cos(x2mx3), 2);

      grad_f[2 * i] += 4. * e0 * pow(e0mx1, 3) + 8. * pow(x[2 * i], 7);
      grad_f[2 * i + 1] += -4. * pow(e0mx1, 3) + 600. * pow(x1mx2, 5);
      grad_f[2 * i + 2] = -600. * pow(x1mx2, 5) + dt;
      grad_f[2 * i + 3] = -dt + 2. * x3m1;
   }

   return true;
}

// return the value of the constraints: g(x)
bool LuksanVlcek4::eval_g(
   Index         /*n*/,
   const Number* x,
   bool          /*new_x*/,
   Index         /*m*/,
   Number*       g
)
{
   for( Index i = 0; i < N_ - 2; i++ )
   {
      g[i] = 8. * x[i + 1] * (x[i + 1] * x[i + 1] - x[i]) - 2. * (1 - x[i + 1]) + 4. * (x[i + 1] - x[i + 2] * x[i + 2]);
   }
   return true;
}

// return the structure or values of the Jacobian
bool LuksanVlcek4::eval_jac_g(
   Index         /*n*/,
   const Number* x,
   bool          /*new_x*/,
   Index         /*m*/,
   Index         nele_jac,
   Index*        iRow,
   Index*        jCol,
   Number*       values
)
{
   if( values == NULL )
   {
      // return the structure of the jacobian

      Index ijac = 0;
      for( Index i = 0; i < N_ - 2; i++ )
      {
         iRow[ijac] = i;
         jCol[ijac] = i;
         ijac++;
         iRow[ijac] = i;
         jCol[ijac] = i + 1;
         ijac++;
         iRow[ijac] = i;
         jCol[ijac] = i + 2;
         ijac++;
      }
      DBG_ASSERT(ijac == nele_jac);
      (void) nele_jac;
   }
   else
   {
      // return the values of the jacobian of the constraints

      Index ijac = 0;
      for( Index i = 0; i < N_ - 2; i++ )
      {
         values[ijac] = -8. * x[i + 1];
         ijac++;
         values[ijac] = 6. - 8. * x[i] + 24. * x[i + 1] * x[i + 1];
         ijac++;
         values[ijac] = -8. * x[i + 2];
         ijac++;
      }
   }

   return true;
}

//return the structure or values of the Hessian
bool LuksanVlcek4::eval_h(
   Index         n,
   const Number* x,
   bool          /*new_x*/,
   Number        obj_factor,
   Index         /*m*/,
   const Number* lambda,
   bool          /*new_lambda*/,
   Index         nele_hess,
   Index*        iRow,
   Index*        jCol,
   Number*       values
)
{
   if( values == NULL )
   {
      Index ihes = 0;
      for( Index i = 0; i < n - 1; i++ )
      {
         iRow[ihes] = i;
         jCol[ihes] = i;
         ihes++;
         iRow[ihes] = i;
         jCol[ihes] = i + 1;
         ihes++;
      }
      iRow[ihes] = n - 1;
      jCol[ihes] = n - 1;
      ihes++;
      DBG_ASSERT(ihes == nele_hess);
      (void) nele_hess;
   }
   else
   {
      // First the objective
      Index ihes = 0;
      values[0] = 0.;
      values[1] = 0.;
      values[2] = 0.;
      for( Index i = 0; i < N_ / 2; i++ )
      {
         Number e0 = exp(x[2 * i]);
         Number e0mx1 = e0 - x[2 * i + 1];
         Number x1mx2 = x[2 * i + 1] - x[2 * i + 2];
         Number x2mx3 = x[2 * i + 2] - x[2 * i + 3];
         Number s = sin(x2mx3);
         Number ss = s * s;
         Number c = cos(x2mx3);
         Number ddt = 4. * (3. * ss * c * c + 5. * ss * ss) / pow(c, 6);

         // x[2*i] x[2*i]
         values[ihes] += obj_factor * (4. * e0 * pow(e0mx1, 3) + 12 * e0 * e0 * e0mx1 * e0mx1 + 56. * pow(x[2 * i], 6));
         ihes++;
         // x[2*i] x[2*i+1]
         values[ihes] += obj_factor * (-12 * e0 * e0mx1 * e0mx1);
         ihes++;
         // x[2*i+1] x[2*i+1]
         values[ihes] += obj_factor * (3000. * pow(x1mx2, 4) + 12. * e0mx1 * e0mx1);
         ihes++;
         // x[2*i+1] x[2*i+2]
         values[ihes] = -obj_factor * (3000. * pow(x1mx2, 4));
         ihes++;
         // x[2*i+2] x[2*i+2]
         values[ihes] = obj_factor * (3000. * pow(x1mx2, 4) + ddt);
         // x[2*i+2] x[2*i+3]
         values[ihes + 1] = -obj_factor * ddt;
         // x[2*i+3] x[2*i+3]
         values[ihes + 2] = obj_factor * (2. + ddt);
      }

      // Now the constraints
      ihes = 0;
      for( Index i = 0; i < N_ - 2; i++ )
      {
         // x[i] x[i+1]
         values[2 * i + 1] -= lambda[i] * 8.;
         // x[i+1] x[i+1]
         values[2 * i + 2] += lambda[i] * 48. * x[i + 1];
         // x[i+2] x[i+2]
         values[2 * i + 4] -= lambda[i] * 8.;
      }
   }
   return true;
}

void LuksanVlcek4::finalize_solution(
   SolverReturn               /*status*/,
   Index                      /*n*/,
   const Number*              /*x*/,
   const Number*              /*z_L*/,
   const Number*              /*z_U*/,
   Index                      /*m*/,
   const Number*              /*g*/,
   const Number*              /*lambda*/,
   Number                     /*obj_value*/,
   const IpoptData*           /*ip_data*/,
   IpoptCalculatedQuantities* /*ip_cq*/
)
{ }
